1. Andrews, J. F. and E. A. Pearson. Kinetics and characteristics of volatile acid production in anaerobic fermentation processes. International Journal for Air and Water Pollution Research 9, 439-461, 1965.
2. Arun, V., T. Mino, and T. Matsuo. Biological mechanisms of acetate uptake mediated by carbohydrate consumption in excess phosphorus removal systems. Water Research 22, 565-570, 1988.
3. Atlas, R. M. Microbiology- Fundamentals and Applications. Macmillan, New York, NY, 1984.
4. Boone, D. R., Whitman, W. B., and P. Rouvière. Diversity and taxonomy of methano-gens. In Methanogenesis: Ecology, Physiology, Biochemistry & Genetics, J. G Ferry, ed„ Chapman & Hall, New York, NY, pp. 35-80, 1993.
5. Brock, T. D., M. T. Madigan, J. M. Martinko, and J. Parker. Biology of Microorganisms. Seventh Edition, Prentice Hall, Englewood Cliffs, NJ, 1994.
6. Brown, C. M. and A. H. Rose. Effects of temperature on composition and cell volume of Candida utilis. Journal of Bacteriology 97, 261-272, 1969.
7. Bruce, A. M. and H. A. Hawkes. Biological filters. In Ecological Aspects of Used-Water Treatment, Vol. 3, C. R. Curds and H. A. Hawkes, eds.. Academic Press. New York. NY, pp. 1-111, 1983.
8. Bryers, J. D. and C. A. Mason. Biopolymer particulate turnover in biological waste treatment systems: a review. Bioprocess Engineering 2, 95-109, 1987.
9. Comeau. Y., K. J. Hall, R. E. W. Hancock and W. K. Oldham. Biochemical model for enhanced biological phosphorus removal. Water Research 20, 1511-1521. 1986
10. Cooke, W. B. Trickling filler ecology. Ecology 40. 273-291. 1959.
11. Curds, C. R. Protozoa. In Ecological Aspects of Used-Water Treatment. Vol. 1. C R. Curds and H. A. Hawkes, eds.. Academic Press, New York, NY, pp. 203-268, 1975.
12. Dold, P. L., G. A. Ekama and G. v. R. Marais. A general model for the activated sludge process. Progress in Water Technology 12(6), 47-77, 1980.
13. Eikelboom, D. H. Filamentous organisms observed in bulking activated sludge. Water Research 9, 365-388, 1975.
14. Focht, D. D. and A. C. Chang. Nitrification and denitrification processes related to waste water treatment. Advances in Applied Microbiology 19, 153-186, 1975.
15 Grady, C. P. L. Jr.. and R. E. Roper Jr. A model for the bio-oxidation process which incorporates the viability concept. Water Research 8, 471-483, 1974.
16. Grady, C. P. L. Jr., G. Aichinger, S. F Cooper and M. Naziruddin. Biodégradation kinetics for selected toxic/hazardous organic compounds. In Proceedings of the 19H9 AWMAiEl'A International Symposium on Hazardous Waste Treatment: Biosystems for Pollution Control. Air and Waste Management Association, Pittsburgh, PA, pp. 141153, 1989.
17. Gujer, W. The effect of particulate organic material on activated sludge yield and oxygen requirement. Progress in Water Technology 12(6), 79-95, 1980.
18. Gujer, W. and A. J. B. Zehnder. Conversion processes in anaerobic digestion Water Science and Technology 15(8/9), 127-167, 1983.
19. Hadjipetrou, L. P., J. P. Gerrits. F. A. G. Teulings. and A. H. Stouthamer. Relation between energy production and growth of Aerobacter aerogenes. Journal of General Microbiology 36, 139-150, 1964.
20. Hamilton, W. A. Microbial energetics and metabolism. In Micro-Organisms in Action: Concepts and Applications in Microbial Ecology, J. M. Lynch and J. E. Hobbie, eds.. Blackwell Scientific Publications, Palo Alto, CA, pp. 75-100, 1988.
21. Hao, O. J., P. F. Strom and Y. C. Wu. A review of the role of Nocardia-\\Y.c filaments in activated sludge foaming. Water SA 14, 105-110, 1988.
22. Hawkes, H. A. The applied significance of ecological studies of aerobic processes. In Ecological Aspects of Used-Water Treatment, Vol. 3, C. R. Curds and H. A. Hawkes. eds.. Academic Press, New York, NY, pp. 173-333, 1983.
23. Heijnen, J. J. and J. P. van Dijken. In search of a thermodynamic description of biomass yields for the chemotrophic growth of microorganisms. Biotechnology and Bioengineering 39, 833-858, 1992.
24. Henze, M. Nitrate versus oxygen utilization rates in wastewater and activated sludge systems. Water Science and Technology, 18(6), 115-122, 1986.
25. Henze, M. The influence of raw wastewater biomass on activated sludge oxygen respiration rates and denitrification rates. Water Science and Technology 21(10/11), 603607, 1989.
26. Henze, M., C. P. L. Grady Jr., W. Gujer, G. v. R. Marais and T. Malsuo. A general model for single-sludge wastewater treatment systems. Water Research 21, 505-515, 1987.
27. Herbert, D. A. A theoretical analysis of continuous culture systems. In Continuous Culture of Microorganisms, Society of Chemical Industry, London, Monograph No. 12, pp. 21-53, 1960.
28. Hettling, L. J., D. R. Washington and S. S. Rao. Kinetics of the steady-state bacterial culture. II. Variation in synthesis. Proceedings of the 19th Industrial Waste Conference. Purdue University Engineering Extension Series No. 117, pp. 687-715, 1964.
29. Hobson, P. N. and B. G. Shaw. The bacterial population of piggery waste anaerobic digesters. Water Research 8, 507-516, 1974.
30. Hoover, S. R. and N. Porges. Assimilation of dairy wastes by activated sludge. II. The equations of synthesis and rate of oxygen utilization. Sewage and Industrial Wastes 24, 306-312, 1952.
31. Jenkins, D., M. G. Richard and G. T. Daigger. Manual on the Causes and Control of Activated Sludge Bulking and Foaming. 2nd ed. Lewis Publishers, Chelsea, MI, 1993.
32. Kelly, D. P. Autotrophy: Concepts of lithotrophic bacteria and their organic metabolism. Annual Review of Microbiology 25, 177-210, 1971.
33. Kirsch, E. J. Studies on the enumeration and isolation of obligate anaerobic bacteria from digesting sewage sludge. Developments in Industrial Microbiology 10, 170-176, 1969.
34. Knight, G. C„ E. M. Seviour, R. J. Seviour, J. A. Soddell, K. C. Lindrea, W. Strachan, B. De Grey, and R. C. Bayly. Development of the microbial community of a full scale biological nutrient removal activated sludge plant during start-up. Water Research 29, 2085-2093, 1995.
35. Knowles, R. Denitrification. Microbiological Reviews 46, 43-70, 1982.
36. Lawrence, A. W. and P. L. McCarty. Unified basis for biological treatment design and operation. Journal of the Sanitary Engineering Division, ASCE 96, 757-778, 1970.
37. Lotter, L. H., M. C. Wentzel, R. E. Loewenthal, G. A. Ekama and G. v. R. Marais. A study of selected characteristics of Acinetobacter ssp. isolated from activated sludge in anaerobic/anoxic/aerobic and aerobic systems. Water SA 12, 203-208, 1986.
38. Mah, R. A. ESE Notes. University of North Carolina, 6, 1, 1969.
39. Marr, A. G., E. H. Nilson and D. J. Clark. The maintenance requirement of Escherichia coli. Annals of the New York Academy of Science 102, 536-548, 1963.
40. Mason, C. A., J. D. Bryers and G. Hamer. Activity, death and lysis during microbial growth in a chemostat. Chemical Engineering Communications 45, 163-176, 1986.
41. Mason, C. A., G. Hamer and J. D. Bryers. The death and lysis of microorganisms in environmental processes. FEMS Microbiology Reviews 89, 373-401, 1986.
42. McCarty, P. L. The methane fermentation. In Principles and Applications of Aquatic Microbiology, H. Heukelekian and N. C. Dondero, eds., John Wiley and Sons, New York, NY, pp. 314-343, 1964.
43. McCarty, P. L. Anaerobic waste treatment fundamentals. Public Works 95(9), 107- 112; (10), 123-126; (11), 91-94; (12), 95-99, 1964.
44. McCarty, P. L. Energetics of organic matter degradation. In Water Pollution Microbiology, R. Mitchell, ed., John Wiley and Sons, Inc., New York, NY, pp. 91-118, 1972.
45. McCarty, P. L. and C. F. Brodersen. Theory of extended aeration activated sludge. Journal, Water Pollution Control Federation 34, 1095-1103, 1962.
46. McClintock. S. A., J. H. Sherrard, J. T. Novak and C. W. Randall. Nitrate versus oxygen respiration in the activated sludge process. Journal, Water Pollution Control Federation 6«. 342-350. 1988.
47. McKinney, R. E. Mathematics of complete mixing activated sludge. Journal of the San-uan■ Engineering Division, ASCE 88(SA3), 87- 113. 1962.
48. Mobarry, B. K.. M. Wagner, V. Urbain, B. E. Riltmann, and D. A. Stahl. Phylogenetic probes lor analyzing abundance and spatial organization of nitrifying bacteria. Applied and Environmental Microbiology 62. 2156-2162. 1996.
49. Muck, R. E. and C. P. L. Grady Jr. Temperature effects on microbial growth in C'STR's. Journal of the Environmental Engineering Division, ASCE 100. 1147-1 163. 1974.
51). Orhon. D. and N. Artan. Modeling of Activated Sludge Systems. Teehnomic Publishing. Lancaster, PA. 1994.
51 Pace, N. R. New perspectives on the natural microbial world: molecular microbial ecology. ASM Sews 62. 463-470, 1996.
52 Painter. H. A. Microbial transformation of inorganic nitrogen. Progress in Water Technology 8(4.5). 3-29, 1977.
53. Painter. H. A. Metabolism and physiology of aerobic bacteria and fungi. In Ecological Aspects of Used-Water Treatment. Vol. 2, C. R. Curds and H. A. Hawkes, eds., Academic Press. New York, NY. pp. 11-75, 1983.
54. Palumbo. A. and 1,. D. Witter. Influence of temperature on glucose utilization by I'seit-domonas fluorescens. Applied Microbiology 18. 137- 141, 1969.
55 Papen, H.. R. von Berg, I. Hinkel, B. Thoene and H. Rennenberg. Heterotrophic nitrification bv Alcaligenes faecalis: NO.. NO, . N O. and NO production in exponentially growing cultures. Applied and Environmental Microbiology 55. 2068 -2072. 1989.
56. Payne. W. J. Energy yield and growth of heterotrophs. AnnuaI Review of Microbiology 24. 17-52, 1970.
57. Pike, E. B. Aerobic bacteria. In Ecological Aspects of Used-Water Treatment. Vol. I, C. R. Curds and H. A. Hawkes, eds.. Academic Press, New York, NY, pp. 1-63. 1975.
58. Pike. E. B. and C". R. C'urds. The microbial ecology of the activated sludge process. In Microbial Aspects oj Pollution. G. Sykes and E. A. Skinner, eds.. Academic Press, New York. NY. pp. 123-148, 1971.
59. Pipes, W. O. The ecological approach to tile study of activated sludge. Advances m Applied .Microbiology». 77-103, 1966.
60. Pirt. J. S. Maintenance energy of bacteria in growing cultures. Proceedings of the Royal Society (London). Series R 163, 224-231. 1965.
(»1. Postgate. J. R. Viability measurements and the survival of microbes under minimum stress. Advances in Microbial Physiology 1. 1-23, 1967.
62. Postgate. J. R. and J. R. Hunter. The survival of starved bacteria Journal of (ieneral Microbiology 29, 233-263. 1962.
63. Ramanathan. M. and A. F. Gaudy Jr. Studies on sludge yield in aerobic systems. Proceedings of the 26th Industrial Wuste Conference. Purdue University Engineering Extension Series No. 14(1, pp. 665-675. 1971.
64 Rittmann, B. E., W. Bae, E. Namkung and C.-J Lu. A critical evaluation of microbial products formation in biological processes. Water Science and Technology 19(7). 517528. 1987.
65 Rossello-Mora, R. A., M. Wagner, R. Amunn, and K.-H. Schleifer. The abundance of Zooglea ramigera in sewage treatment plants. Applied and Environmental Microbiology 61. 702-707, 1995.
66. Sahm. H. Anaerobic wastewater treatment. Advances in Riochemical Engineering and Riotechnology 29, 83- 115, 1984.
67. Savvver. ('. N.. P. L. McCarty. and (J. F. Parkin. Chemistry for Environmental Engineering. 4th ed.. McGraw-Hill Book Company, New York. NY. 1995.
68. Scheifinger, C. C\, B. Linchan, and M. J. Wolin. H- production by Selenomonas ruminan-tium in the absence and presence of methanogenic bacteria. Applied Microbiology 29. 480-483, 1975.
69. Senez. J. C. Some considerations on the energetics of bacterial growth. Bacteriological Reviews 26, 95-107, 1962.
70. Sezgin, M.. D. Jenkins and D. S. Parker. A unified theory of filamentous activated sludge bulking. Journal, Water Pollution Control Federation 50, 362-381, 1978.
71. Shea, T. G., W. A. Pretorius, R. D. Cole, and E. A. Pearson. Kinetics of hydrogen assimilation in the methane fermentation. Water Research 2, 833-848, 1968.
72. Stephenson, T. Acinetobacter: its role in biological phosphate removal. In Biological Phosphate Removal from Wastewaters, R. Ramadori, ed., Pergamon Press, Elmsford. New York, NY, pp. 313-316, 1987.
73. Tempest. D. W. and O. M. Neijssel. The status of Yvlr and maintenance energy as biologically interpretable phenomena. Annual Review of Microbiology 38, 459-486. 1984.
74. Tempest. D. W., D. Herbert and P. J. Phipps. Studies on the growth of Aerobacter aero-genes at low dilution rates in a chemostat. In Microbial Physiology and Continuous Culture. edited by E. O. Powell et al., Her Majesty's Stationery Office. London, pp. 240253, 1967.
75. Toerien, D. F. and W. H. J. Hattingh. Anaerobic digestion. I. The microbiology of anaerobic digestion. Water Research 3, 385-416, 1969.
76. Tomlinson, T. G. and I. L. Williams. Fungi. In Ecological Aspects of Used Water Treatment, Vol. 1,C. R. Curds and H. A. Hawkes, eds., Academic Press, New York. NY. pp. 93-152. 1975.
77. Topiwala, H. and C. G. Sinclair. Temperature relationships in continuous culture. Bio technology and Bioenginecring 13. 795-813, 1971.
78. Verstraete, W. and M. Alexander. Heterotrophic nitrification in samples of natural ecosystems. Environmental Science and Technology 7, 39-42. 1973.
79. Wagner, M„ R. Erhart, W. Manz, R. Amann, H. Lemmer, D. Wedi. and K.-H. Schleifer. Development of an rRNA-targeted oligonucleotide probe specific for the genus Acinelo-bacter and its application for in situ monitoring in activated sludge. Applied anil Environmental Microbiology 60. 792-800, 1994.
80. Weddle. C. L. and D. Jenkins. The viability and activity of activated sludge. Water Research 5, 621-640, 1971.
81. Wentzel, M. C\, L. H. Lotter, G. A. Ekama, R. E. Loewenthal, and G. v. R. Marais. Evaluation of biochemical models for biological excess phosphorus removal. Water Science and Technology 23, 567-576, 1991.
82. Wentzel, M. C, L. H. Lotter, R. E. Loewenthal and G. v. R. Marais Metabolic behavior of Acinetobacter ssp. in enhanced biological phosphorus removal—A biochemical model. Water SA 12, 209-224, 1986.
83. Woese. C. R., O. Kandler, and M. L. Wheelis. Towards a natural system of organisms: proposal for the domains of Archaea, Bacteria, and Eukarva. Proceedings of the National Academy of Science USA 87. 4576-4579, 1990.
84. Wolfe, R. S. 1776-1996: Alessandro Volta's combustible air. ASM News 62. 529-534. 1996.
85. Yoshioka, T.. H. Terai and Y. Saijo. Growth kinetics studies of nitrifying bacteria by the immunofluorescent counting method. Journal of General and Applied Microbiology 28, 169-180, 1982.
86. Zinder, S. H. Microbiology of anaerobic conversion of organic wastes to methane: Recent developments. ASM News 50, 294-298, 1984.
87. Zinder, S. II. Physiological ecology of methanogens. In Methanogenesis: Ecology, Physiology, Biochemistry & Genetics, J. G. Ferry, ed.. Chapman & Hall, New York. NY, pp. 128-206, 1993.
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